In vitro diagnostic device with integrated plasma separator

The invention claimed is: 1. A lab-on-a-chip cartridge comprising: a) a housing comprising a plurality of side wall members defining first, second, third and fourth separate chambers on the interior of the cartridge; b) each of the first, second and third chambers having a pump interface associated therewith; c) at least the first chamber having a port through which a fluid may be introduced into the first chamber; d) a filter membrane rotatably mounted in the fourth chamber so as to define a gap between an outer surface of the filter membrane and an inner surface of the side wall member defining the fourth chamber; e) a first passageway extending between the first chamber and the gap in the fourth chamber; f) a first flow path extending between the fourth chamber and the second chamber to permit fluid flow between an inner surface of the filter membrane and the second chamber, with a lab-on-a-chip device comprising an integrated circuit positioned within the first flow path and configured to contact fluid flowing into the second chamber; g) a second flow path extending between the fourth chamber and the third chamber to permit fluid flow between the gap in the fourth chamber and the third chamber; and h) an interface in an exterior surface of the fourth chamber configured to couple a drive device with the filter membrane for rotating the filter membrane. 2. The lab-on-a-chip cartridge of claim 1 wherein the housing further comprises a top plate, a bottom plate, and an intermediate plate between the top and bottom plates defining the side wall members, with the first flow path, second flow path, pump interfaces, port and drive device interface being contained within one of the top and bottom plates. 3. The lab-on-a-chip cartridge of claim 2 further comprising a second interface associated with the top plate to permit at least one or more of thermal regulation of the lab-on-a-chip device, imaging of a surface of the lab-on-a-chip device, and the application, control and sensing of electrical signals to and from the lab-on-a-chip device. 4. The lab-on-a-chip cartridge of claim 2 , wherein the intermediate plate includes a cut-out configured to receive the lab-on-a-chip device. 5. The lab-on-a-chip cartridge of claim 1 wherein each of the pump interfaces comprises a recessed well sealed with a flexible diaphragm. 6. The lab-on-a-chip cartridge of claim 1 wherein the port includes an adhesive seal. 7. The lab-on-a-chip cartridge of claim 1 wherein the port is positioned between the pump interface of the first chamber and the first passageway. 8. The lab-on-a-chip cartridge of claim 1 wherein each of the second and third chambers includes a port through which a fluid may be extracted. 9. The lab-on-a-chip cartridge of claim 8 wherein each port includes an adhesive seal. 10. The lab-on-a-chip cartridge of claim 8 wherein the port of the second chamber is positioned between the pump interface of the second chamber and the first flow path. 11. The lab-on-a-chip cartridge of claim 8 wherein the port of the third chamber is positioned between the pump interface of the third chamber and the second flow path. 12. The lab-on-a-chip cartridge of claim 1 wherein the drive device interface comprises a recessed area. 13. The lab-on-a-chip cartridge of claim 1 wherein the first chamber is a whole blood chamber, the second chamber is a plasma chamber, the third chamber is a red blood cell chamber, the fourth chamber is a separation chamber, the first flow path is a plasma flow path, and the second flow path is a red blood cell flow path. 14. The lab-on-a-chip cartridge of claim 1 wherein the filter membrane includes magnetic material configured to couple the filter membrane to the drive device. 15. The lab-on-a-chip cartridge of claim 1 wherein the first, second, and third chambers are elongated and oriented substantially parallel to each other. 16. The lab-on-a-chip cartridge of claim 15 wherein: the fourth chamber is substantially circular, the second chamber is positioned between the first and third chambers, and a portion of the fourth chamber is positioned between the first and third chambers. 17. The lab-on-a-chip cartridge of claim 1 wherein the first flow path is substantially linear. 18. The lab-on-a-chip cartridge of claim 1 wherein the first flow path has a non-uniform width, with a portion of the first flow path having a maximum width being at least partially aligned with the lab-on-a-chip device. 19. The lab-on-a-chip cartridge of claim 1 wherein the second flow path is generally U-shaped. 20. A method of extracting plasma from whole blood and analyzing it with a lab-on-a-chip cartridge comprising: a. withdrawing whole blood from a blood source and introducing the whole blood into a first chamber of the lab-on-a-chip cartridge through an injection port; b. pumping the whole blood into a separation chamber of the lab-on-a-chip cartridge with a filter membrane; c. rotating the filter membrane and filtering the whole blood so that plasma passes through the filter membrane and flows out of the separation chamber and into a plasma flow path of the lab-on-a-chip cartridge where the plasma contacts a lab-on-a-chip device of the lab-on-a-chip cartridge, and red blood cells flow out of the separation chamber and into a red blood cell fluid flow path of the lab-on-a-chip cartridge; and d. analyzing the plasma with the lab-on-a-chip device, wherein the lab-on-a-chip device comprises an integrated circuit.